KR102268600B1 - Broadcasting system capable of self diagnosis - Google Patents

Abstract

Disclosed is a broadcasting system capable of self-diagnosis. The broadcasting system capable of self-diagnosis includes: a signal input part inputting an audio signal; a signal processing part mixing the audio signal inputted from the signal input part; a signal amplifying part amplifying the audio signal inputted from the signal processing part; a broadcasting line control part selecting at least one of a plurality of speakers and transmitting the audio signal inputted from the signal amplifying part to the selected speaker, and then, monitoring a line to the speaker; a monitoring part monitoring the operation condition of each of the signal processing part and the signal amplifying part using the audio signal inputted from the signal amplifying part and the audio signal outputted from the signal amplifying part; a power distribution part supplying power to each of the signal input part, the signal processing part, the signal amplifying part, the broadcasting line control part, the monitoring part, and the main control part; and a main control part selectively monitoring at least one of the power condition, the communication condition, the audio signal condition, and the speaker line condition of each of the signal processing part, the signal amplifying part, the broadcasting line control part, the monitoring part, and the power distribution part in accordance with a preset scenario. Therefore, the present invention is capable of enabling a manager to easily recognize the operation condition of each piece of equipment in a broadcasting system and handle the same.

Description

Broadcasting system capable of self-diagnosis {BROADCASTING SYSTEM CAPABLE OF SELF DIAGNOSIS}

The present invention relates to a broadcasting system capable of self-diagnosis, and more particularly, to self-diagnose the power state, communication state, audio signal flow, and speaker line state of each equipment in a broadcasting system that processes audio signals according to a preset scenario. , to a broadcasting system capable of self-diagnosis.

In general, a broadcasting system (Public Address System) installed in apartment complexes, schools, government offices, large buildings, ports, airports, shopping malls, etc. controls several speakers in a central system.

For broadcasting, a cable for transmitting power and voice signals is installed by connecting to a speaker for each region/branch, equipment that inputs sound sources for broadcasting from the central system, and an amplifier (AMP) for outputting it through speakers in each region, etc. Various electronic equipment is equipped.

As described above, as a variety of equipment is provided in a broadcasting system, the need to efficiently manage failure diagnosis, maintenance, and repair of such a plurality of equipment is emerging.

The background technology of the present invention is disclosed in 'Broadcasting system having abnormal diagnosis and automatic channel switching function and broadcasting method using the same' of Korean Patent No. 10-1407284 (June 9, 2014).

The present invention has been devised to improve the above problems, and an object according to an aspect of the present invention is to set a preset power state and communication state, audio signal flow and speaker line state of each equipment in a broadcasting system that processes an audio signal. An object of the present invention is to provide a self-diagnosing broadcasting system capable of self-diagnosing according to a scenario.

A broadcasting system capable of self-diagnosis according to an aspect of the present invention includes: a signal input unit for inputting an audio signal; a signal processing unit for mixing the audio signal input from the signal input unit; a signal amplifying unit amplifying the audio signal input from the signal processing unit; a broadcasting line controller for selecting at least one of a plurality of speakers and transmitting the audio signal input from the signal amplifier to the speaker, and monitoring a speaker line to the speaker; a monitoring unit for monitoring operation states of each of the signal processing unit and the signal amplifying unit using the audio signal input from the signal amplifying unit and the audio signal output from the signal amplifying unit; a power distribution unit supplying power to each of the signal input unit, the signal processing unit, the signal amplification unit, the broadcast line control unit, the monitoring unit, and the main control unit; and selectively monitoring at least one of a power state, a communication state, an audio signal state, and a speaker line state of each of the signal processing unit, the signal amplifying unit, the broadcasting line control unit, the monitoring unit, and the power distribution unit according to a preset scenario It is characterized in that it comprises a main control unit.

The signal input unit of the present invention is characterized in that the audio signal of a frequency band that humans cannot hear and an audio signal of a frequency band that humans can hear are selectively input to the signal processing unit.

The monitoring unit of the present invention compares the signal level of the audio signal input from the signal processing unit with a preset reference level and determines whether the signal processing unit is operating normally according to the comparison result.

The monitoring unit of the present invention amplifies the audio signal input from the signal processing unit to the same volume level as the volume level currently set in the signal amplifying unit to generate a reference audio signal, and generates a reference audio signal and the inputted signal from the reference audio signal and the signal amplifying unit. After comparing the audio signals to determine whether they match, it is characterized in that it is determined whether the signal amplifying unit is operating normally according to the determination result.

The broadcast line control unit of the present invention includes an impedance of the speaker in a broadcast state in which the audio signal input from the signal amplifying unit is output to the speaker, and a broadcast that does not output the audio signal input from the signal amplifying unit to the speaker. Disconnection or short circuit of the speaker line is monitored based on each impedance of the speaker in the off state.

The main control unit of the present invention is characterized in that it monitors the power connection state of the power distribution unit in real time.

The power distribution unit of the present invention selectively selects at least one of constant power and switch power according to whether each of the signal input unit, the signal processing unit, the signal amplification unit, the broadcast line control unit, the monitoring unit, and the main control unit is always operated. It is characterized by supplying.

The main control unit of the present invention supplies power to each of the signal input unit, the signal processing unit, the signal amplification unit, the broadcast line control unit, and the monitoring unit through the power distribution unit, and then includes the signal input unit, the signal processing unit, and the It is characterized in that it receives voltage information from each of the signal amplifying unit, the broadcast line control unit, and the monitoring unit to monitor the power state.

The main control unit of the present invention supplies power to each of the signal processing unit, the signal amplifying unit, and the broadcasting line control unit through the power distribution unit, and then communicating with the signal processing unit, the signal amplifying unit and the broadcasting line control unit. characterized by monitoring.

The main control unit of the present invention is characterized in that the signal processing unit, the signal amplifying unit, and monitoring the communication connection state in the order of the broadcast line control unit.

A power control module installed in each of the signal input unit, the signal processing unit, the signal amplifying unit, the broadcasting line control unit, and the monitoring unit of the present invention to selectively cut off the power supplied from the power distribution unit according to whether the current operation is in progress It is characterized in that it further comprises.

The power control module of the present invention includes a power control switch for cutting off power supplied to the operation circuits of the signal input unit, the signal processing unit, the signal amplification unit, the broadcast line control unit, and the monitoring unit from the power distribution unit; and a power control unit for controlling the power control switch according to whether the current operation is performed.

A broadcasting system capable of self-diagnosis according to an aspect of the present invention self-diagnoses the power state, communication state, audio signal flow, and speaker line state of each equipment in the broadcasting system that processes audio signals according to a preset scenario.

A broadcasting system capable of self-diagnosis according to another aspect of the present invention outputs a self-diagnosis result of the broadcasting system to a manager so that the manager can easily recognize and cope with the operating state of each equipment in the broadcasting system.

1 is a block diagram of a broadcasting system capable of self-diagnosis according to an embodiment of the present invention.
2 is a diagram illustrating output power of a power distribution unit according to an embodiment of the present invention.
FIG. 3 is a diagram illustrating devices that receive regular power and switch power, respectively, according to an embodiment of the present invention.
4 is a block diagram of a power control module according to an embodiment of the present invention.

Hereinafter, a broadcasting system capable of self-diagnosis according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings. In this process, the thickness of the lines or the size of the components shown in the drawings may be exaggerated for clarity and convenience of explanation. In addition, the terms to be described later are terms defined in consideration of functions in the present invention, which may vary according to intentions or customs of users and operators. Therefore, definitions of these terms should be made based on the content throughout this specification.

1 is a block diagram of a broadcasting system capable of self-diagnosis according to an embodiment of the present invention, FIG. 2 is a diagram showing output power of a power distribution unit according to an embodiment of the present invention, and FIG. 3 is a diagram of the present invention It is a view showing devices that receive regular power and switch power, respectively, according to an embodiment, and FIG. 4 is a block diagram of a power control module according to an embodiment of the present invention.

1 to 4, the self-diagnosis broadcasting system according to an embodiment of the present invention includes a signal input unit 10, a signal processing unit 20, a signal amplifying unit 30, a broadcasting line control unit 40, It includes a speaker output unit 50 , a power distribution unit 60 , a monitoring unit 70 , a main control unit 80 , and a power control module 90 .

The signal input unit 10 inputs an audio signal to the signal processing unit 20 . A variety of sound sources may be employed for the signal input unit 10 , and a microphone, a compact disk (CD)/universal serial bus (USB), or a time signal may be employed as the sound source, but is not limited thereto.

The signal input unit 10 selectively inputs an audio signal in a frequency band that humans cannot hear and an audio signal in a frequency band that humans can hear according to the control signal of the main controller 80 . Both an audio signal in a frequency band that humans cannot hear and an audio signal in a frequency band that humans can hear may be used for self-diagnosis.

That is, the signal input unit 10 outputs an audio signal of a human audible frequency band in a broadcasting state in which an audio signal is output to a speaker, and an audio signal of a frequency band that a human cannot hear during self-diagnosis of the broadcasting system. can also be printed.

An audio signal of a frequency band that cannot be heard by humans may be inputted from the signal input unit 10 , but may also be input from the signal processing unit 20 to be described later.

Meanwhile, the self-diagnosis may be performed even in a broadcast state in which an audio signal is output.

The signal processing unit 20 mixes the audio signal input from the signal input unit 10 and operates the broadcasting system. The signal processing unit 20 includes an audio mixer and an operation management personal computer (PC) therein.

The operation management PC controls the operation of the broadcasting system according to the control command of the administrator. To this end, the operation management PC receives various control commands for outputting audio signals to the speaker from the manager.

The control command may include, but is not limited to, an on/off command of a broadcasting system, a volume control command, a sound source selection command, a menu setting command, and the like.

The audio mixer mixes the audio signal input from the signal input unit 10 and inputs it to the monitoring unit 70 . An audio mixer is a device for mixing audio signals, and is also called a mixing console, a mixing desk, a sound board, and the like. The audio mixer can control the intensity, tone, and surround image of an audio signal, and generates a mixed audio signal.

The audio mixer is obvious to those skilled in the art and a detailed description thereof will be omitted herein.

For reference, in the present embodiment, the operation management PC and the audio mixer are provided in the signal processing unit 20 as an example, but the operation management PC and the audio mixer may be independently provided.

The signal amplifying unit 30 amplifies the audio signal input from the monitoring unit 70 and transmits the amplified audio signal to the monitoring unit 70 . The signal amplifier 30 may include a plurality of power amplifiers (power amplifiers 1 to N). The power amplifier may be provided for each channel, and amplifies the audio signal of each channel and transmits the amplified audio signal to the monitoring unit 70 .

The broadcast line control unit 40 selects a speaker to which an audio signal is to be output, and transmits the audio signal input from the monitoring unit 70 to the selected speaker through a speaker line. To this end, the broadcast line control unit 40 may include a plurality of speaker selectors (speaker selector 1 to speaker selector N). These speaker selectors may be provided for each channel, and each speaker selector transmits an audio signal of each channel to a corresponding speaker.

In addition, the broadcast line control unit 40 monitors each speaker line and transmits the monitoring result to the main control unit 80 . The speaker line is connected between the speaker selector and the speaker, and transmits the audio signal output from the speaker selector to the speaker.

In this case, the broadcast line control unit 40 measures the impedance of the speaker in a broadcast state in which an audio signal is output to the speaker or by measuring the impedance of the speaker in a broadcast-off state in which an audio signal is not output to the speaker, thereby causing disconnection of the speaker line. Alternatively, short circuits can be monitored.

For example, the broadcast line control unit 40 measures the impedance value of the speaker in the broadcast off state and in the broadcast on state with respect to the speaker line. In the broadcast off state, the signal input unit 40 according to the control signal of the main controller 80 The audio signal input from (10) is output to measure the impedance of the speaker, and when the broadcast is on, the impedance of the speaker line is measured using the audio signal currently being broadcast, and then the speaker line is short-circuited and disconnected using this impedance. to detect

In this case, the broadcast line control unit 40 may detect a short circuit or a disconnection of the speaker line for each channel. That is, since a plurality of speaker lines are provided for each channel, each speaker selector of the broadcast line control unit 40 detects a short circuit and a disconnection for each speaker line, and transmits the monitoring result for each speaker line to the main control unit 80 . .

The speaker output unit 50 outputs an audio signal input from the broadcast line control unit 40 . The speaker output unit 50 may include a plurality of speakers (speakers 1 to N). These speakers may be provided for each channel, and each speaker outputs an audio signal input from a corresponding speaker selector.

The monitoring unit 70 monitors the operation state of each of the signal processing unit 20 and the signal amplifying unit 30 using the audio signal input from the signal amplifying unit 30 and the audio signal output from the signal amplifying unit 30 . do.

First, the monitoring unit 70 receives an audio signal from the signal amplifying unit 30 . In this case, the monitoring unit 70 compares the signal level of the audio signal input from the signal processing unit 20 with a preset reference level, and determines whether the signal processing unit 20 operates normally according to the comparison result.

The reference level is a level of an audio signal previously set for determining whether the audio signal mixed by the audio mixer is a normal audio signal. Accordingly, if the level of the audio signal input from the signal processing unit 20 is less than the reference level, the monitoring unit 70 determines the audio signal state as bad, and transmits the determination result to the main control unit 80 .

In addition, the monitoring unit 70 monitors the operation state of the signal amplifying unit 30 by comparing the audio signal input from the signal amplifying unit 30 for each channel with a preset reference audio signal.

That is, the monitoring unit 70 generates a reference audio signal by amplifying the audio signal input from the signal processing unit 20 to the same volume level as the volume level currently set in the signal amplifying unit 30 .

Then, the monitoring unit 70 compares the reference audio signal with the audio signal input from the signal amplifying unit 30 to determine whether they match. The monitoring unit 70 determines that the signal amplifying unit 30 is normal when the reference audio signal and the audio signal input from the signal amplifying unit 30 match, and determines that the signal amplifying unit 30 is abnormal when they do not match. .

As such, the monitoring unit 70 may determine whether the audio signal input from the signal processing unit 20 is accurately amplified by the signal amplifying unit 30 according to its volume level.

In this process, the main control unit 80 can set the volume level in various ways. When an audio signal is input from the signal processing unit 20, it can increase or decrease in real time, and the state of the signal amplifier 30 can be monitored for each volume level. can

Meanwhile, the main control unit 80 turns off the speaker line when monitoring the signal amplifying unit 30 .

The power distribution unit 60 supplies power to each of the signal input unit 10 , the signal processing unit 20 , the signal amplifying unit 30 , the broadcast line control unit 40 , the monitoring unit 70 , and the main control unit 80 . .

Power is divided into regular power and switch power. Each of the regular power and the switch power may include both DC power and AC power.

The constant power is power that is continuously supplied regardless of whether the corresponding equipment is operating, and the switch power is the power that is turned on or off depending on whether the corresponding equipment is operating.

The constant power is supplied to the power distribution unit 60 and the main control unit 80, and the switch power is the signal input unit 10, the signal processing unit 20, the signal amplifying unit 30, the broadcasting line control unit 40, and the monitoring unit. 70 is supplied.

The power distribution unit 60 supplies constant power and switch power to the signal input unit 10, the signal processing unit 20, the signal amplifying unit 30, the broadcasting line control unit 40, the monitoring unit 70 and It is supplied to the main control unit (80).

That is, the power distribution unit 60 receives constant power and supplies constant power to the main control unit 80 , and the signal input unit 10 , the signal processing unit 20 , the signal amplification unit 30 , and the broadcast line control unit 40 . ) and the monitoring unit 70 are supplied with switch power.

As such, unnecessary power consumption is reduced by preventing power from being supplied when the signal input unit 10, the signal processing unit 20, the signal amplifying unit 30, the broadcasting line control unit 40, and the monitoring unit 70 are not in operation. can be reduced

Meanwhile, the main control unit 80 supplies power to each of the signal input unit 10 , the signal processing unit 20 , the signal amplification unit 30 , the broadcast line control unit 40 , and the monitoring unit 70 through the power distribution unit 60 . can supply

Then, the main control unit 80 requests a response as to whether power is normally supplied to each of the signal input unit 10 , the signal processing unit 20 , the signal amplification unit 30 , the broadcast line control unit 40 , and the monitoring unit 70 . do. In response to this response request, each of the signal input unit 10 , the signal processing unit 20 , the signal amplifying unit 30 , the broadcasting line control unit 40 , and the monitoring unit 70 receives the voltage supplied from the power distribution unit 60 . voltage information is transmitted to the main control unit 80 . Accordingly, the main control unit 80 receives the signal input unit (10) according to the voltage information transmitted from each of the signal input unit 10, the signal processing unit 20, the signal amplifying unit 30, the broadcasting line control unit 40, and the monitoring unit 70. 10), the signal processing unit 20, the signal amplifying unit 30, the broadcasting line control unit 40, and the monitoring unit 70, respectively, to monitor the power state.

In addition, the main control unit 80 provides power to each of the signal input unit 10 , the signal processing unit 20 , the signal amplification unit 30 , the broadcast line control unit 40 , and the monitoring unit 70 through the power distribution unit 60 . can be supplied, and a communication connection state with the signal input unit 10 , the signal processing unit 20 , the signal amplification unit 30 , the broadcast line control unit 40 , and the monitoring unit 70 can be monitored.

In this case, the main control unit 80 transmits voltage information from each of the signal input unit 10 , the signal processing unit 20 , the signal amplification unit 30 , the broadcast line control unit 40 , and the monitoring unit 70 as described above. It is possible to monitor the communication connection state with these equipment based on whether or not, but periodically with the signal input unit 10 , the signal processing unit 20 , the signal amplification unit 30 , the broadcast line control unit 40 and the monitoring unit 70 . It is possible to check the communication connection status for each of them by performing message communication for checking the operation status.

At the same time, the main control unit 80 performs the normal operation of each of the signal input unit 10 , the signal processing unit 20 , the signal amplification unit 30 , the broadcast line control unit 40 and the monitoring unit 70 through the message communication described above. You can also check whether

The main control unit 80 monitors the communication connection state in the order of the signal processing unit 20 , the signal amplifying unit 30 , and the broadcasting line control unit 40 , and the monitoring order is not particularly limited.

On the other hand, the main control unit 80, the signal processing unit 20, the signal amplification unit 30, the broadcast line control unit 40, the monitoring unit 70, and the power distribution unit 60 according to a preset scenario each power state and It monitors communication status, audio signal status and speaker line status, and outputs monitoring results. In this case, the main control unit 80 may output the above-described monitoring result through a monitor of an administrator terminal or an operation management PC.

Here, the scenario is the power state and communication state, audio signal state, and speaker line of each of the signal processing unit 20, the signal amplifying unit 30, the broadcasting line control unit 40, the monitoring unit 70, and the power distribution unit 60. It is preset to monitor the status. The main control unit 80 controls each of the signal processing unit 20, the signal amplifying unit 30, the broadcasting line control unit 40, the monitoring unit 70 and the power distribution unit 60 according to this scenario to perform diagnosis. carry out

On the other hand, the power control module 90 is installed in each of the signal processing unit 20, the signal amplifying unit 30, the broadcasting line control unit 40, and the monitoring unit 70, depending on whether the current operation from the power distribution unit 60 Selectively cut off the supplied power.

That is, the power control module 90 cuts off the power supply if it is not currently operating even though power is currently supplied to each of the signal processing unit 20 , the signal amplifying unit 30 , the broadcasting line control unit 40 , and the monitoring unit 70 . do.

The power control module 90 includes a power control switch 92 and a power control unit 91 .

The power control switch 92 is the signal input unit 10, the signal processing unit 20, the signal amplification unit 30, the broadcast line control unit 40, and the monitoring unit 70 from the power distribution unit 60, each operation circuit Cut off the power supplied to (100).

Here, the operation circuit 100 is installed in each of the signal input unit 10 , the signal processing unit 20 , the signal amplifying unit 30 , the broadcasting line control unit 40 , and the monitoring unit 70 to perform a unique operation. It is a device that performs That is, the operation circuit 100 installed in the signal input unit 10 inputs an audio signal, the operation circuit 100 installed in the signal processing unit 20 mixes the audio signal, and the operation circuit installed in the broadcast line control unit 40 . 100 selects a speaker to output an audio signal and outputs an audio signal to the corresponding speaker, and the operation circuit 100 of the monitoring unit 70 operates the signal processing unit 20 and the signal amplifier 30 respectively. monitor the status.

The power control unit 91 blocks the power supplied from the power distribution unit 60 to the operation circuit 100 by controlling the power control switch 92 according to the current operation. That is, the main control unit 80 determines whether each of the signal input unit 10 , the signal processing unit 20 , the signal amplification unit 30 , the broadcast line control unit 40 , and the monitoring unit 70 operates.

In this case, the main control unit 80 provides a corresponding power supply to the currently operating equipment among the signal input unit 10 , the signal processing unit 20 , the signal amplifying unit 30 , the broadcasting line control unit 40 , and the monitoring unit 70 . By controlling the control unit 91 to turn on the power control switch 92, power is supplied to the operation circuit 100 of the corresponding equipment.

On the other hand, the main control unit 80 includes the signal input unit 10 , the signal processing unit 20 , the signal amplifying unit 30 , the broadcasting line control unit 40 , and the monitoring unit 70 for equipment that is not currently in operation. Power is not supplied to the operation circuit 100 by controlling the power control unit 91 to turn off the power control switch 92 .

As described above, the self-diagnostic broadcasting system according to an embodiment of the present invention self-diagnoses the power state, communication state, audio signal flow, and speaker line state of each equipment in the broadcasting system that processes audio signals according to a preset scenario. .

In addition, the broadcasting system capable of self-diagnosis according to an embodiment of the present invention outputs the self-diagnosis result of the broadcasting system to the administrator so that the administrator can easily recognize and cope with the operating state of each equipment in the broadcasting system.

Implementations described herein may be implemented in, for example, a method or process, an apparatus, a software program, a data stream, or a signal. Although discussed only in the context of a single form of implementation (eg, only as a method), implementations of the discussed features may also be implemented in other forms (eg, in an apparatus or a program). The apparatus may be implemented in suitable hardware, software and firmware, and the like. A method may be implemented in an apparatus such as, for example, a processor, which generally refers to a computer, a microprocessor, a processing device, including an integrated circuit or programmable logic device, or the like. Processors also include communication devices such as computers, cell phones, portable/personal digital assistants ("PDAs") and other devices that facilitate communication of information between end-users.

Although the present invention has been described with reference to the embodiment shown in the drawings, this is merely exemplary, and it is understood that various modifications and equivalent other embodiments are possible by those skilled in the art. will understand Accordingly, the true technical protection scope of the present invention should be defined by the following claims.

10: signal input unit 20: signal processing unit
30: signal amplification unit 40: broadcasting line control unit
50: speaker output unit 60: power distribution unit
70: monitoring unit 80: main control unit
90: power control module 91: power control unit
92: power control switch 100: operation circuit

Claims (12)

a signal input unit for inputting an audio signal;
a signal processing unit for mixing the audio signal input from the signal input unit;
a signal amplifying unit amplifying the audio signal input from the signal processing unit;
a broadcasting line control unit for selecting at least one of a plurality of speakers and transmitting the audio signal input from the signal amplifying unit to the speaker, and monitoring a speaker line to the speaker;
a monitoring unit for monitoring operation states of each of the signal processing unit and the signal amplifying unit using the audio signal input from the signal amplifying unit and the audio signal output from the signal amplifying unit;
a power distribution unit supplying power to each of the signal input unit, the signal processing unit, the signal amplification unit, the broadcast line control unit, and the monitoring unit; and
Selectively monitoring at least one of a power state and communication state, an audio signal state, and a speaker line state of each of the signal processing unit, the signal amplifying unit, the broadcasting line control unit, the monitoring unit, and the power distribution unit according to a preset scenario comprising a main control unit;
The monitoring unit generates a reference audio signal by amplifying the audio signal input from the signal processing unit to the same volume level as the volume level currently set in the signal amplifier, and receives the reference audio signal and the audio signal input from the signal amplifier. After comparing and determining whether or not they match, it is determined whether the signal amplifying unit is operating normally or not
A power control module installed in each of the signal input unit, the signal processing unit, the signal amplifying unit, the broadcast line control unit, and the monitoring unit to selectively cut off the power supplied from the power distribution unit according to current operation. and,
The power control module may include a power control switch for cutting off power supplied to the operation circuits of the signal input unit, the signal processing unit, the signal amplification unit, the broadcast line control unit, and the monitoring unit from the power distribution unit; and a power control unit for controlling the power control switch according to whether the current operation is performed or not. The method of claim 1, wherein the signal input unit
A broadcasting system capable of self-diagnosis, characterized in that the audio signal of a frequency band that humans cannot hear and an audio signal of a frequency band that humans can hear are selectively input to the signal processing unit. According to claim 1, wherein the monitoring unit
The self-diagnosis broadcasting system of claim 1, wherein the signal level of the audio signal input from the signal processing unit is compared with a preset reference level and the signal processing unit is normally operated according to the comparison result. delete The method of claim 1, wherein the broadcast line control unit
Impedance of the speaker in a broadcast state in which the audio signal input from the signal amplifier is output to the speaker, and impedance of the speaker in a broadcast off state in which the audio signal input from the signal amplifier is not output to the speaker A broadcasting system capable of self-diagnosis, characterized in that the disconnection or short circuit of the speaker line is monitored based on each. The broadcasting system of claim 1, wherein the main control unit monitors a power connection state of the power distribution unit in real time. 7. The method of claim 6, wherein the power distribution unit
A person characterized in that the signal input unit, the signal processing unit, the signal amplification unit, the broadcasting line control unit, the monitoring unit, and the main control unit selectively supply at least one of a constant power and a switch power according to whether each of the regular operation Broadcast system capable of diagnosis. The method of claim 6, wherein the main control unit
After supplying power to each of the signal input unit, the signal processing unit, the signal amplifying unit, the broadcasting line control unit, and the monitoring unit through the power distribution unit, the signal input unit, the signal processing unit, the signal amplifying unit, and the broadcasting line A broadcasting system capable of self-diagnosis, characterized in that it receives voltage information from each of the control unit and the monitoring unit and monitors the power state. The method of claim 6, wherein the main control unit
After supplying power to each of the signal processing unit, the signal amplifying unit, and the broadcasting line control unit through the power distribution unit, the signal processing unit, the signal amplifying unit and the broadcasting line control unit are monitored for a communication connection state. Broadcasting system capable of self-diagnosis. 10. The method of claim 9, wherein the main control unit
A broadcasting system capable of self-diagnosis, characterized in that the signal processing unit, the signal amplifying unit, and the broadcasting line control unit monitor the communication connection status in order. delete delete

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